Degeneration and death,by apoptosis and necrosis,of the pavement and chloride cells in the gills of the teleost Oreochromis mossambicus

Summary Degeneration and death of branchial epithelial cells were studied in an African cichlid fish. In both freshwater and seawater fish the superficially located pavement cells are sloughed off at the end of their lifecycle. This process is preceded by degeneration via a process of cytoplasmic shrinkage and condensation related to apoptotic (physiologically controlled) cell death. The chloride cells are pleomorphic, i.e., accessory, mature, and degenerating cells. Degeneration of chloride cells mainly occurs by apoptosis. Degenerating cells show shrinkage and densification of cytoplasm and nuclei, and swelling of the tubular system; these cells are then separated from the ambient water by pavement cells. They are finally phagocytosed and digested by macrophages. Apoptosis of chloride cells, but not of pavement cells, is greatly stimulated when the fish are in seawater; this reflects an increase in cellular turnover of the chloride cells. Accidental cell death (necrosis) of pavement cells or chloride cells is rarely observed in fully adapted freshwater and seawater fish. Its incidence increases in the first few days following transfer of fish from fresh water to seawater.     

Degeneration of interstitial gland cells of normal and irradiated dog ovary

The interstitial gland cells of the ovary were studied by electron microscopy in seven Beagle dogs during advanced metestrus. Additionally, the findings of three dogs with an increased activation of the interstitial gland cells after 12 Gy whole-body X-irradiation were also presented. Three groups of interstitial gland cells were distinguished: the immature, the mature and the degenerating cells. The steroid-specific cell organelles of mature interstitial cells were highly developed after irradiation-induced stimulation. At the onset of generation, a circular arrangement of dilated endoplasmic vesicles (demarcation channel) characterized the cells of non-irradiated and of irradiated ovaries. During the early stage of degeneration, different degrees of nuclear shrinkage and of vacuolation of the cytoplasm were seen. A lace-like vacuolation was common in the irradiated ovaries. During the advanced stage of degeneration, the cysts ruptured with resultant shedding of the cytoplasmic organelles into the intercellular space. A new cellular membrane was simultaneously reconstituted and a fibrocyte-like cell appeared. The process is referred as "secretory degeneration" and is presented as a hypothesis.     

Programmed cell death in Xenopus laevis spinal cord, tail and other tissues, prior to, and during, metamorphosis

Programmed cell death is necessary for the shaping and remodelling of nervous and non-nervous tissues during development. Amphibia, whose body undergoes profound modifications during metamorphosis, are particularly useful models for studying the relationship between cell death in muscles and other non-nervous tissues on the one hand, and in the nervous system connected with these tissues on the other hand. We checked the occurrence of apoptotic cells (identified by TUNEL labelling) in different organs and regions from hatching (stages 35-36) to climax (stages 63-64) in the African Clawed Frog Xenopus laevis. Some organs (e.g., skin and digestive tract) contained apoptotic cells during the entire period studied. In transitory organs (cement gland and gills), a single wave of cell death occurred during the regression of these tissues. In order to compare the timing of cell death in the spinal cord with that of tail regression, we counted the number of TUNEL-positive cells in spinal cord sections taken from animals between stages 54 and 64. Three-dimensional reconstructions using confocal microscopy of vibratome slices immunostained for the detection of c-Jun-like protein accumulated in the cytoplasm of apoptotic cells showed numerous cells at various degrees of degeneration. Many of these cells still presented the morphological characteristics of neurones. The peak of apoptosis was found at stage 58, preceding tail regression. This suggests that neural cell death is not a consequence but rather an element upstream in the chain of events leading to tail degeneration.     

Spontaneous degeneration of germ cells in normal rat testis: assessment of cell types and frequency during the spermatogenic cycle.

The occurrence of degenerating germ cells in the cycle of the seminiferous epithelium was measured in testicular tissues from eight normal adult rats. Testes were perfusion fixed, embedded in epoxy resin and, after sectioning a total of 180 randomly selected blocks at 1 microns, stained sections were examined by light microscopy; all cross-sectioned seminiferous tubules were categorized into one of 14 stages of the spermatogenic cycle. The number of degenerating cells per tubule was recorded in 2103 tubules. Degenerating germ cells were not detected at stages II-VI, and only rarely at stage VII (n = 366 tubules) in which one primary spermatocyte and one step 19 spermatid degenerated. All other stages exhibited a greater incidence of degenerative germ cells, particularly at stage XIV where, on average, the frequency of degenerating cells per round seminiferous tubule was about 40 times greater than at stage VII. The results indicated that, in the normal adult rat testis, the germ cells are least at risk of degeneration as they pass through stage VII.     

Morphological organization of the male brood pouch epithelium of Syngnathus abaster Risso (Teleostea, Syngnathidae) before, during, and after egg incubation

The morphological organization of the male brood pouch epithelium of Syngnathus abaster, before, during, and after the breeding period, was observed by light and electron microscopy. Before gestation, the epithelium of the pouch wall was compact and consisted of three kinds of cells: typical epithelial cells (pavement cells), mitochondria-rich cells (MR cells), and, presumably, differentiating MR cells. In this stage, very few capillaries were observed beneath the epithelium. During egg incubation, the capillaries increased in number and size, large intercellular spaces formed among epithelial cells at their basal sides, MR cells were abundant, and differentiating MR cells were only occasionally observed. After incubation, MR cells degenerated by necrosis and apoptosis. The intercellular spaces between the epithelial cells disappeared and the number and size of the capillaries beneath the epithelium decreased. The presence of MR cells during gestation and their degeneration after incubation suggest that these cells play a pivotal role in the physiological functions of the brood pouch. The similar cytological characteristics of syngnathid pouch MR cells and chloride cells of the teleostean gills suggests that the Syngnathidae brood pouch is involved in osmoregulation of the fluid surrounding the developing embryos.     

Light and electron microscopic study of the degeneration and early regeneration of olfactory epithelium in the mouse.

Degeneration and early regeneration of olfactory epithelium from two strains of mice was studied at the light and electron microscopic levels from 12 hours to 3 days following nasal irrigation with 1% aqueous solution of zinc sulfate (ZnSO4) (a compound known to selectively damage olfactory epithelium). Distinct patterns of degeneration and stages of regeneration were evident following treatment. During the first 24 hours after treatment three progressive manifestations of the degenerative process were seen: (1) a relatively mild condition which was characterized by surface irregularities produced by cell protrusions, highly vacuolated cytoplasm, presence of large lysosome-like bodies and prominent intercellular spaces, (2) a more severe condition in which large areas of the epithelium were detached from the basement membrane cellular debris was present in the nasal chamber, and (3) a condition of total or near-total denudation of the epithelium of olfactory mucosa. The basal lamina was continuous and intact in most regions and the integrity of the subadjacent connective tissue was mostly well-preserved. Nerve bundles of the fila olfactoria were noted in varying degrees of degeneration during the course of the experiment. The most advanced neural degeneration was seen 24 to 72 hours after treatment. Onset of regeneration was suggested by the appearance of a simple squamous layer of cells above the basement membrane 48 to 72 hours after treatment. In addition to the simple epithelium a stratified epithelium consisting of two to four cell layers was also observed at this time. Glandular cells, containing secretory granules identical to those in Bowman's glandular cells, were noted in an apparent process of migration from the lamina propria into the the stratified epithelial layer. The last mentioned observation supports the proposition that new supportive epithelial cells originate from cells of Bowman's gland.     

The ultrastructure of chloride cells in the gills of the teleostOreochromis mossambicus during exposure to acidified water

Summary Branchial chloride cells, which actively take up ions in the gills of freshwater fish, were studied in tilapia (Oreochromis mossambicus) exposed to sublethally acidified freshwater. Structural damage of cells, resulting in cell death by necrosis, only occurred transiently, when the reduction of water pH was acute rather than gradual. The most prominent effects of water acidification were the rapid increase in the number of chloride cells and the changes in frequency of the different stages of the chloride cell cycle. In the opercular inner epithelium, a twofold increase in cells occurred 48 h after gradual acidification. Cell density stabilized after 4 weeks at a level 5 times that of control fish. Four transitory stages were distinguished in the chloride cell cycle: accessory or replacement cells, immature, mature, and degenerating (apoptotic) cells. In control fish, mature chloride cells dominated (over 50%) with immature and apoptotic cells totalling about 40%. After 4 weeks in acid water, only 13% of the cells were mature. Immature and apoptotic cells dominated, each representing about 40% of the total number of chloride cells. Mature cells apparently age rapidly under these conditions. Thus, chloride cells turn over quickly in acid water, with a minor increase in ion transport capacity of the gills. This conclusion is supported by the observation that opercular and branchial Na⁺/K⁺ ATPase activities in treated fish are only 40%–50% higher than in controls.     

Dynamics of apoptosis in the ovarian follicle cells during the late stages of Drosophila oogenesis

In the present study, we demonstrate the apoptotic events of the ovarian follicle cells during the late stages of oogenesis in Drosophila melanogaster. Follicle cell morphology appears normal from stage 10 up to stage 14, exhibiting a euchromatic nucleus and a well-organized cytoplasm. First signs of apoptosis appear at the anterior pole of the egg chamber at stage 14A. They are characterized by loss of microvilli at the apical cell membrane, alterations in nuclear morphology, such as chromatin condensation and convolution of the nuclear membrane, and also by condensation and vacuolization of the cytoplasm. During the following stage 14B, the follicle cell nuclei contain fragmented DNA as is demonstrated by acridine orange staining and TUNEL (TdT-mediated dUTP nick end-labeling) assay. Finally, the apoptotic follicle cells seem to detach from the eggshell when the mature egg chamber exits the ovariole. The detached follicle cells exhibit condensed nuclear chromatin, a disorganized cytoplasm with crowded organelles and are surrounded by epithelial cells. The above results seem to be associated with the abundant phagocytosis that we observed at the entry of the lateral oviducts, where the epithelial cells contain apoptotic cell bodies. Additionally, we tested the effect of etoposide treatment in the follicular epithelium and found that it induces apoptosis in a stage- and site-specific manner. These observations suggest a possible method of absorption of the apoptotic follicle cells that prevents the blockage of the ovarioles and helps the regular production of mature eggs.     

Degeneration and apoptosis of endometrial cells in the bitch

The relationships between changes in plasma progesterone concentrations, degeneration of the luminal epithelium, the occurrence of apoptosis of endometrial cells and endometrial leucocyte populations in the bitch were determined. Mature bitches (n = 15) were euthanized and necropsied when in diestrus (Days 7-75, n = 12) or in anestrus (Days 10, 32 and 53). Degeneration of the luminal epithelium was observed in bitches in late diestrus (Days 38-75, n = 5) when plasma progesterone concentrations were decreasing and in anestrus (Days 10 and 32, n = 2) when plasma progesterone concentrations were < 0.5 ng/mL. Endometrial leucocyte populations increased after degeneration of the luminal epithelium (around Day 42 of diestrus). Apoptosis was mainly observed in the basal glandular epithelial cells and endothelial cells of blood capillaries in all except anestrous bitches. Very few apoptotic cells were found in the superficial glandular epithelial cells and stromal cells. Higher apoptotic indices were detected in the basal glandular epithelium on Days 12-42 of diestrus than at other stages. Therefore, apoptosis of glandular basal epithelial cells occurred mainly in early diestrus, degeneration of cells of the luminal epithelium occurred from mid-diestrus to early anestrus, and the increase in leucocyte numbers may have been a consequence and not a cause of luminal epithelial degeneration.     

Germ cell degeneration and intercellular bridges in the human fetal ovary

Summary Intercellular bridges between developing germ cells were observed in human fetal ovaries at 10 to 20 weeks gestation. Bridges were frequently found between cells in early stages of degeneration, with similar regressive changes being present in the conjoined cells. In advanced stages of cellular degeneration, bridges were less frequently found and were generally distorted and partially disrupted. Similarity in appearance of adjacent degenerating cells was common, even in late stages of degeneration. These observations suggest that cellular interconnection may be responsible for synchronous degeneration of germ cells during oogenesis.The author thanks Mrs. Lucy A. Conner for her valuable technical assistance. This research was supported by U.S.P.H.S. grant HD-05727.     

In vivo time course of morphological changes and DNA degradation during the degeneration of castration-induced apoptotic prostate cells

The in vivo time course of the morphological changes and DNA degradation in castration-induced apoptotic prostate cells was studied from the earliest to the latest stage of the degeneration process. To study this problem, we first induced apoptotic prostate cells in rats by castration for 3 days and then promptly and continuously blocked the death of healthy prostatic cells in the castrated rats by in vivo testosterone replacement. Because testosterone replacement could not stop the irreversible lysis of already damaged prostate cells, apoptotic cells at different stages of the degeneration process were eliminated sequentially from the prostate after the healthy prostate cells had been protected. Prostate cells at the earliest stage of apoptosis at the time when the castrated rats received testosterone replacement disappeared last. By tracing the morphological and DNA degradation of apoptotic cells after hormone treatment, we estimated the time course of prostate cell death from the early to the final stage. In the morphological evolution of apoptotic prostate cells, the clumping of nuclear chromatin, the degeneration of cytoplasm and the involution of the cell surface occurred and progressed simultaneously, resulting in the rapid formation of apoptotic bodies that were gradually digested by other cells. The DNA ladders of apoptotic cells were progressively cleaved into a mononucleosomal subunit that was further degraded at an additional site, generating a heterogeneous population of small nucleotides. The final digestion of DNA fragments occurred within the apoptotic bodies. The whole course of prostate cell death after castration took about 44 h.     

Programmed cell death and heterolysis of larval epithelial cells by macrophage-like cells in the anuran small intestine in vivo and in vitro.

The degenerative processes in the larval small intestine of Xenopus laevis tadpoles during spontaneous metamorphosis and during thyroid hormone-induced metamorphosis in vitro were examined by electron microscopy. Around the beginning of spontaneous metamorphic climax (stages 59-61), both apoptotic bodies derived from larval epithelial cells and intraepithelial macrophage-like cells suddenly increase in number. The macrophage-like cells become rounded and enlarged because of numerous vacuoles containing the apoptotic bodies. Mitotic profiles of the macrophage-like cells, however, are localized in the connective tissue where different developmental stages of macrophage-like cells are present. After stage 62, the intraepithelial macrophage-like cells decrease in number, while large macrophage-like cells which include the apoptotic bodies and retain intact cell membranes and nuclei appear in the lumen. Degenerative changes similar to those during spontaneous metamorphosis described above could be reproduced in vitro. In tissue fragments isolated from the small intestine of stage 57 tadpoles and cultured in the presence of thyroid hormone, the number of intraepithelial macrophage-like cells reaches its maximum around the 3rd day of cultivation when the larval epithelial cells most rapidly decrease in number. These results suggest that the rapid degeneration of larval epithelial cells occurs not only because of apoptosis of the epithelial cells themselves but also from heterolysis by macrophages. The macrophages probably originate in the connective tissue, actively proliferate, migrate into the larval epithelium around the beginning of metamorphic climax, and are finally extruded into the lumen.     

Changes in the lipid inclusion/Sertoli cell cytoplasm area ratio during the cycle of the human seminiferous epithelium

The area occupied by Sertoli cell lipid inclusions--electron-lucent lipid vacuoles (LLV) and electron-dense lipid droplets (DLD)--at each stage of the cycle of the seminiferous epithelium was measured on electron micrographs in young adults and elderly men, and expressed as the ratio "area occupied by lipid inclusions/area occupied by the Sertoli cell cytoplasm". For LLV this ratio increased from stage I to stage III, and decreased from stage IV to stage VI in young adults. These results suggest that the development of LLV is synchronized with the spermatogenic process: the residual bodies released in stages I and II are phagocytized by Sertoli cells and transformed into LLV; the amounts of LLV decrease in the subsequent stages of the cycle and increase again when new residual bodies appear. In elderly men the ratio LLV/Sertoli cell cytoplasm was 1.9-2.9 times higher than in young adults at each stage of the cycle. This increase may be related to the increased germ-cell degeneration observed in ageing testes, DLD were less abundant than LLV and the DLD/Sertoli cell cytoplasm ratio did not undergo cyclic changes in young adults or elderly men.     

Morphogenesis of the antenna of the male silkmoth, Antheraea polyphemus. II. Differential mitoses of 'dark' precursor cells create the Anlagen of sensilla

The antenna of the male silkmoth Antheraea polyphemus develops from a one-layered, flattened epidermal sac during the pupal phase. Within the first day post-apolysis (developmental stages 1 and 2), this epithelium differentiates into 'sensillogenic' and 'nonsensillogenic' regions, while numerous slender 'dark cells' interpreted as the precursor cells of sensilla arise in the former. Approximately between the first and second day post-apolysis (developmental stage 3), the dark cells retract to the apical pole of the epidermis, assume a round shape, and undergo a series of differential mitoses with spindles usually oriented parallel to the epidermal surface. These mitoses finally yield the Anlagen of the olfactory sensilla trichodea, each consisting of mostly 6-7 dark cells arranged side by side. In most of the Anlagen, 3-4 of these cells are situated more basally, each giving off a slender apical process which together are arranged in a fascicle. These are the prospective 2-3 sensory neurons plus the thecogen cell, which most probably is a sister cell of the former. Three additional cells are arranged more apically and partly enclose the fascicle of presumed sensory and thecogen cell processes. These are interpreted as the trichogen plus 2 tormogen cells, one of the latter degenerating later during development. In the basal region of the sensillogenic epidermis, massive signs of cell degeneration have been found. At stage 3, the basal epidermal feet in the non-sensillogenic regions have assumed a more uniform orientation as compared with the preceding stages.     

Structural and ultrastructural differentiation of the thyroid gland during embryogenesis in the grass snake Natrix natrix L. (Lepidosauria, Serpentes)

The differentiation of the thyroid primordium of reptilian species is poorly understood. The present study reports on structural and ultrastructural studies of the developing thyroid gland in embryos of the grass snake Natrix natrix L. At the time of oviposition, the thyroid primordium occupied its final position in the embryos. Throughout developmental stages I-IV, the undifferentiated thyroid primordium contained cellular cords, and the plasma membranes of adjacent cells formed junctional complexes. Subsequently, the first follicular lumens started to form. The follicular lumens were of intracellular origin, as in other vertebrate species, but the mechanism of their formation is as yet unclear. At developmental stages V-VI, the thyroid anlage was composed of small follicles with lumens and cellular cords. Cells of the thyroid primordium divided, and follicles were filled with a granular substance. At developmental stage VI, the cells surrounding the follicular lumen were polarized, the apical cytoplasm contained dark granules and the Golgi complex and the rough endoplasmic reticulum (RER) developed gradually. Resorption of the colloid began at developmental stage VIII. At the end of this stage, the embryonic thyroid gland was surrounded by a definitive capsule. During developmental stages IX-X, the follicular cells contained granules and vesicles of different sizes and electron densities and a well-developed Golgi apparatus and RER. At developmental stage XI, most follicles were outlined by squamous epithelial cells and presented wide lumens filled with a light colloid. The Golgi complex and RER showed changes in their morphology indicating a decrease in the activity of the thyroid gland. At developmental stage XII, the activity of the embryonic thyroid gradually increased, and at the time of hatching, it exhibited the features of a fully active gland.     

Immunolocalization of Vacuolar-Type H(+)-ATPase in the Yolk-Sac Membrane of Tilapia (Oreochromis mossambicus) Larvae

To investigate the involvement of the yolk-sac membrane in ion absorption, developmental changes in whole-body cation contents, cellular localization of vacuolar-type H(+)-ATPase (V-ATPase), and size and density of pavement and chloride cells in the yolk-sac membrane were examined in tilapia (Oreochromis mossambicus) larvae in fresh water (FW) and those transferred to seawater (SW) at 2 days before hatching (day-2). The whole-body content of Na(+) in embryos and larvae adapted to both FW and SW increased constantly from day-2 to day 10, although they were not fed through the experiment. The yolk-sac membrane of FW larvae at days 0 and 2 showed V-ATPase immunoreactivity in pavement cells, but not in chloride cells. No positive immunoreactivity was detected in SW larvae. Whole-mount immunocytochemistry showed that some pavement cells were intensively immunoreactive, whereas others were less or not immunoreactive. Electron-microscopic immunocytochemistry revealed that V-ATPase immunoreactivity was present in the apical regions of pavement cells in FW larvae, especially in their ridges. The pavement cells in FW larvae were significantly smaller in size but higher in density than those in SW. These results suggest that pavement cells are the site of active Na(+) uptake in exchange for H(+) secretion through V-ATPase in FW-adapted tilapia during early life stages.     

A comparative light and electron microscopic analysis of microspore and tapetum development in fertile and cytoplasmic male sterile radish

To gain further insight into the abortive stages and ultrastructural changes leading to pollen degeneration of a novel cytoplasmic male sterile radish 805A, we compared differences of cellular and subcellular structure of sterile anther with fertile anther by light and electron microscopy analysis. Two types of locule degeneration in sterile anther were detected, of which the time of degeneration occurred and completed was different. In type I, abnormality of pollen mother cells (PMCs) and tapetal cells, including condensation of cytoplasm and large vacuoles within tapetal cells, was shown at PMC stage. In type II, meiosis and early tetrad stage progressed normally except for large vacuoles that appeared in tapetal cells. Ultrastructural alterations of the cellular organization were observed in the type II locules, such as chromatin condensation at the periphery of the nucleus and degeneration of the karyotheca, compared with normal pollen development. The results suggested that the cytoplasmic male sterility anther degeneration was probably caused by dysfunctions of tapetum and vacuolation of tapetum, PMCs, and microspores. Thus, the identical factors, which induced CMS in the same cytoplasmic and nuclear genetic background, might affect development of tapetum and microspore at different stages during the cytoplasmic male sterile 805A anther development.     

Replacement of midgut epithelium in the greater wax moth,Galleria mellonela,during larval-pupal moult

The epithelium of larval midgut of the greater wax moth, Galleria mellonela, was replaced during the larval-pupal moult. The development of this moth was tentatively divided into 11 stages, from the full-grown larva of last instar to the 4-day-old pupa. The midgut at each stage was observed for (1) overall structure, (2) the position of goblet cells, and (3) the appearance of the yellow body. Light microscopy revealed that cell death in the midgut began in a cocoon-spinning larva (stage II), when pigments in the stemmata started to migrate. Before drastic remodeling started to occur, cytoplasmic projections in the goblet cavities were transformed. The larval midgut changed markedly at stage III, when the pigments left the stemmata. The epithelium of the larval midgut dropped as a whole into the lumen, transforming into the yellow body. Simultaneously, a pupal midgut epithelium developed. Electron microscopy of the columnar cells of a stage III larva showed that microvilli and mitochondria looked normal even though the nucleus with condensed heterochromatin resembled an apoptotic nucleus of vertebrate and higher plant cells. Caspase-3-like protease activity was restricted to the larval midgut and increased in parallel with the formation of the yellow body. The results indicate that the replacement of the larval midgut is facilitated by a typical apoptotic process.     

Programmed cell death of the ovarian nurse cells during oogenesis of the silkmoth Bombyx mori

In the present study, we describe the features of programmed cell death of the ovarian nurse cells occurring during vitellogenesis of the silkmoth Bombyx mori. At developmental stage 5, the nurse cells occupy one-half of the follicular volume and obtain a rather spherical shape, while the nurse cell nuclei appear large and elongated, forming impressive projections. At the following stage, stage 6, the nurse cells decrease in size and their shape becomes elliptic. The nuclei remain elongated, being also characterized by large lobes. The lobes of the ramified nurse cell nuclei seem to retain the nucleus in the center of the cell during the dumping of the nurse cell cytoplasm into the growing oocyte. At stage 7, membrane enclosed vacuoles can be easily detected into the nurse cells cytoplasm. Ultrastructural analysis and fluorescent microscopy using mono-dansyl-cadaverine staining of these vacuoles also reveal that they represent autolysosomes. Caspase activity is detected during stage 7, as it is demonstrated by using the Red-VAD-FMK staining reagent. At developmental stages 8 and 9, the nurse cells exhibit chromatin condensation, DNA fragmentation and caspase activity. Finally, during the following stage 10, the nuclear remnants are assembled into apoptotic vesicles, which, after being phagocytosed, are observed in the cytoplasm of adjacent follicle cells. We propose that apoptosis and autophagy operate synergistically during vitellogenesis of B. mori, in order to achieve an efficient and rapid clearance of the degenerated nurse cell cluster.     

Ultrastructural observations on the organogenesis of the posterior silk gland of the silkworm, Bombyx mori

In the early stages of development (0 to 48 hr after organogenesis) the posterior silk gland cells of the silkworm, Bombyx mori, have characteristics of undifferentiated cells, that is, there are a number of free ribosomes in the cytoplasm and development of rough endoplasmic reticulum (rER) and Golgi bodies is very poor. Mitotic cells are frequently found. At ～ 60 hr when differentiation of the silk gland to the posterior, middle, and anterior divisions is completed, mitotic cells were no longer observable and the posterior silk gland is now composed of two rows of cells regularly packed forming a tubular structure. Differentiation of the cytoplasm is, however, not yet apparent and only a slight proliferation of rER can be observed. At 84 to 144 hr, proliferation of rER and transformation of rER from lamellar to vesico-tubular configuration are observed and Golgi vacuoles begin to enlarge. Just before hatching, the ultrastructures of cells are very similar to those of the later stage of the fifth instar when fibroin is synthesized extensively; the cytoplasm is filled with vesico-tubular rER, Golgi bodies, free secretory granules of fibroin, and mitochondria. Fibroin is probably synthesized, transported, and secreted in a manner similar to that in the fifth instar larvae.